1. ENVR 132/TOXC 142/BIOC142 Biochemical & Molecular Toxicology
Induction of Metabolism by Toxicants
Instructor:
Stephen S. Ferguson, Ph.D.

2. Induction: Definitions and Principles
The process of increasing the amount or the activity of a protein.
A homeostatic mechanism for regulating enzyme production in a barrier organ, such as the liver, intestine, kidney.
In enzymology, an inducer usually combines with and deactivates/activates a regulatory protein which leads to increased gene expression.

3. P450 Enzyme Induction
Induction can cause marked increases in P450 composition (>20-fold) and chemical clearance or bioactivation.
As a result, induction can increase tolerance to some toxicants while enhancing the toxicity of others.
Induction can decrease the therapeutic effect of drugs by increasing the rate and pattern of metabolism.
Xenobiotics are known to induce enzymes that play a major or no role in their biotransformation (e.g., omeprazole vs. ethanol).

4. Why Is It Important to Assess Enzyme Induction?
Failure of therapy (e.g. OC’s, epilepsy, HIV)
Drug tolerance with auto-induction
Xenobiotic toxicity potentiated
Complicated dosing regimen
Chemical carcinogenesis potentiated
Perturbation of endogenous substrate metabolism/homeostasis
Hepatomegaly & proliferation of cellular ER & peroxisomes

5. Internal Exposure to Natural and Man-made Chemicals
drugs
industrial chemicals
pesticides
pollutants
alkaloids
cigarette smoke
cruciferous vegetables (indole-3-carbinol)
secondary plant metabolites
toxins produced by molds, plants, and animals
pyrolysis products in cooked food

6. Types of P450 Inducers
Many “prototypical” inducers of specific families or subfamilies of P450 enzymes
CYP1A inducers: 3-MC, BNF, omeprazole, TCDD
CYP3A inducers: rifampin, dexamethasone, troglitazone
CYP2B inducers: phenobarbital, PCBs, phenytoin
CYP4A inducers: fibrates
CYP2E1 inducers: ethanol, isoniazid
Some overlap in “specificities” of inducers
An inducer for one family of enzymes may also suppress another family (e.g., BNF)

7. Induction of Rat Liver P450 Enzymes by Prototypical Inducers In Vivo
In Vivo Induction in Male Rats
Control Activity
Induced Activity
CYP1A
BNF
152  27
3,320  183
CYP2B PB
24  4
1,460  180
CYP3A
PCN
2,460  780
12,693  2,255
CYP4A
CLO
489  52
10,693  620
CYP1A, EROD; CYP2B, PROD; CYP3A, testosterone 6b-hydroxylation;
CYP4A, lauric acid 12-hydroxylation.

8. Induction and Inhibition of P450 in Mice Treated with PB or SKF525A: [14C-methyl]aminopyrine

9. Rifampin Effects on Triazolam Disposition
 Placebo
Serrum triazolam (ng/ml)
Villikka et al., Clin Pharmacol Ther 1997;61:8-14.

10. Consequences of Cytochrome P450 Enzyme Induction
Increased toxic effect
Acetaminophen Alcohol, 3-MC
Bromobenzene, CCl4 Phenobarbital
Increased bioactivation
Cyclophosphamide Macrolides, pesticides
Increased tumor formation
Altered disposition of endogenous substrates
Altered cellular and physiological function
proliferation of peroxisomes and SER
increased liver weight
endocrine disruption
Porphyria, chloracne
PCDDs, azobenzenes, biphenyls (PCBs), naphthalene

11. Effects of Inducers on Rodent Liver Physiology and Function

12. Acetaminophen Metabolism and Toxicity
~60%
~35%
CYP2E*
CYP1A
CYP3A
*induced by ethanol, isoniazid,
phenobarbital
Protein adducts,
Oxidative stress,
Toxicity
NAPQI
N-acetyl-p-benzoquinone imine

13. Endocrine Disruption
UGT1A

14. Molecular Mechanisms of P450 Enzyme Induction

15. General Mechanisms of P450 Induction
Receptor-mediated transcriptional activation
Receptor
A macromolecule with which a hormone, drug, or other chemical interacts to produce a characteristic effect.
Two key features:
chemical recognition
signal transduction
Ligand: A chemical that exhibits specific binding to a receptor.
mRNA stabilization
Protein stabilization
Coordinates: Kumar R, Thompson EB (1999). "The structure of the nuclear hormone receptors". Steroids 64 (5): 310–9

16. Enzyme Induction General mechanism of hepatic enzyme induction
protein
activity
mRNA
Gene transcription X
Nuclear Receptor
XR cytosol
XR nucleus
Phase1
Phase 2
transporters
cytoplasm
nucleus
Hepatocyte

17. NR’s and P450 Induction P450 mRNA Transcription I Translation XREM
CAR
PXR
RNA poly II
SRC-1
Transcription
P450
mRNA I
TFs
RXR NR
Translation
P450
XREM
PBREM
Promoter
CYP450 gene
Drug-OH
Drug
Increased Drug
Metabolism

18. Complex Transcriptional Machinery
precursor mRNA
mature mRNA
mRNA degradation
micro RNA
protein translation
protein folding
protein degradation

19. Co-regulation of Target Genes by NR’s
Complementary roles of NR’s in protection against xenobiotic exposure.
Increased expression of the hepatic genes involved in drug metabolism and excretion (e.g., CYP’s, UGT’s, GST’s, transporter proteins).
These target genes represent redundant but distinct layers of defense.
There are overlapping similarities and distinct differences in species’ response to activators of NR’s.

20. Receptors Involved in the Regulation of
CYP Gene Expression

21. Coordinate Regulation of P450’s, UGT’s and Transporters by NR’s
MRP3
Modified from Kast, H. R. et al. J. Biol. Chem. 277: , 2002

22. What is Relevant Induction? Potency and Efficacy
Dose-Response ‘Window’
(Position → potency)
Emax
Magnitude of Response (Efficacy)
Efficacy (e.g. % of PC)
Potency (e.g. EC50)
EC50

23. PAH Inducers in Rat vs. Human
EC50 = /
EC50 = /
CYP1A1 mRNA Hu497
Rat TCDD 1A1 mRNA
EC50 = /
EC50 10X Difference

24. Relationship between In Vitro Potency and Induction In Vivo
EC50 Cmax [Cmax]/EC50 Clinical Relevance
Nifedione No known
Lovastatin No known
Rosiglitazone No known
Simvastatin No known
Troglitazone Yes
Phenytoin Yes
Avasimibe Yes
Rifampicin Yes
Carbamazepine Yes
Clotrimazole 1-5 Topical (Inhibition)
[Cmax]/EC50 < 0.1, induction not likely
1< [Cmax]/ EC50 < 0.1, induction possible
[Cmax]/ EC50 > 1, induction likely

25. Aryl Hydrocarbon Receptor (AhR)
Aryl hydrocarbon receptor (AHR) is a basic helix-loop-helix (bHLH) protein belonging to the Per-Arnt-Sim (PAS) family of transcription factors
It transcriptionally induces expression of hepatic CYP1A1, CYP1A2, and CYP1B1 , as well as several other genes, including some phase II metabolizing enzymes
AHR ligands include PAHs and TCDD

26. AhR Signaling Pathway Cytoplasm Nucleus 90 X L 90 X AhR 90 X L or 90 X
Arnt L
From: Anne Mullen, Advanced Pharmacology, McMaster University, Ontario, CA

27. AhR Signaling Pathway + + AhR/Arnt heterodimer
Increased expression CYP1A1 protein
Increased expression of other gene products
Translation
mRNA IC
XRE
promoter
gene (CYP1A1)
TNGCGTG

28. Nuclear Hormone Receptors
AF-1
DBD
LBD
AF-2
Amino
Carboxy
Modulators interact
with some cofactors
Binding to response
elements of target genes
Ligand and coactivator
binding pockets
Translocase
activity
LBD
NR-LBD
RXR-LBD
NR-LBD
NR-LBD
DBD
DBD
DBD
DBD
DBD 5’ 3’ 5’ 3’ 5’ 3’
Monomers
RXR Heterodimers
Homodimers
ROR
TLX
ERR
NGFI-B
PXR
CAR
PPAR
LXR
FXR
RAR GR ER
RXR
COUP-TF
HNF4
Rev-Erb
GCNF

29. n DRn IRn ERn CYP2B Response elements CYP3A Response elements5’ 3’ n
DRn
IRn
ERn
CYP2B Response elements
CYP3A Response elements
NR1s
DRs
CYP2B TGTACT n=4 TGACCC
CYP2b TGTACT n=4 TGACCT
CYP2B TCTACT n=4 TGACCT
CYP2B TGTACT n=5 TGACCT
CYP3A TGAACT n=3 TGACCC
CYP3A TGACCT n=3 TGAGCT
CYP3A TGACCT n=4 TGAGTT
CYP3A TGAACT n=3 TGAACT
NR2s
ERs
CYP2B TGGACT n=4 TGAACC
CYP2b TCAACT n=4 TGACAC
CYP2B TCAACT n=4 TGACAC
CYP2B TCAACT n=4 TGACAC
CYP3A TGAAAT n=6 GGTTCA
CYP3A TGAACT n=6 AGGTCA
CYP3A TTAACT n=6 AGGTCA
CYP3A TGAACT n=6 AGGTAA
CYP3A TTAACT n=6 AGGTCA
CYP3A TGAAAT n=6 AGTTCA
NR3
CYP2B TGGACT n=4 TGACCC
Other Genes
UGT1A TGAGTT n=4 TAACCT MDR TGAGAT n=6 AGTTCA
rMRP TGAACT n=8 AGTTCA CYP2C CAAACT n=4 TGACCT

30. Nuclear Receptor PXR ? cytoplasm nucleus Activator/Agonist CYP Target
RIF PB ?
PXR
HSP90
translocation?
-mouse-yes
-human-no
PXR
cytoplasm
RXR
nucleus
CAR
RXR
Receptor Conserved across species, but there are differences
PXR
XREM
CYP3A
Activator/Agonist CYP Target
Human RIF CYP3A4
Rat PCN CYP3A1/2
Mouse PCN Cyp3a11

31. Nuclear Receptor CAR: PB Induction-Constitutively Active?
HSP90
CAR
CCRP
CCRP
PP2A
HSP90 OA
CAR
cytoplasm
nucleus
RXR
In cell lines spontaneously translocates to the nucleus
RXR
CAR
PBREM
CYP2B
Emphasize Constitutive Activity and Translocation…need inhibitors and sequestration to study properly
Activator/Agonist Inhibitor/Antagonist CYP Target
Human CITCO, PB, DPH Clotrimazole?, Miclizine? CYP2B6
Rat PB, TCPOBOP Androstenol CYP2B1
Mouse PB, TCPOBOP Androstenol Cyp2b10

32. Similar Binding of PXR and CAR to Promoter Response Elements
Goodwin et al., Mol. Pharmacol., 2001

33. Differential Binding of PXR and CAR to Other Promoter Regions
NR3-2B ER6-3A4
PXR
CAR
RXR
PXR/RXR
CAR/RXR

34. GR/Dex Role in Basal & Induced P450 Expression via CAR/PXR (master regulator)

35. Role of CAR/PXR in lipid metabolism, synthesis, and uptake
Moreau et al Mol. Pharmaceutics

36. PXR & CAR role in Glucose Homeostasis

37. Molecular Basis for the Species Differences in Enzyme Induction

38. Species Differences in the Regulation of CYP3A Enzymes
10mM Rifampicin
10mM SR12813
0.1% DMSO
10mM DTBA
5mM PCN
CYP3A4
Human
CYP3A6
Rabbit
CYP3A23
Rat

39. Species Differences in CYP2B Induction by Phenobarbital

40. Species Differences in CYP1A Induction by Xenobiotics

41. Species Differences in CYP4A Induction by Clofibric Acid
Rat Hepatocytes
Human Hepatocytes
Rat
Human
Lauric acid 12-hydroxylation
Data are mean plus or minus standard deviation of three replicates in the TaqMan assay.
Rat data are consistent with literature reports of EC50 for rat CYP4A induction by clofibric acid.
Human data are consistent with literature reports of EC50 for human CYP4A induction by clofibric acid.
Need to perform this experiment in dog hepatocytes when CYP4A primers and probes are validated.

42. Observations and Questions
Significant species differences are observed in response to inducers.
All major subfamilies of inducible CYP’s (CYP1A, CYP2B, CYP3A, CYP4A) exhibit this behavior.
What is the molecular basis of the species-specific responses?
What is the significance of these differences to predicting human toxicity?

43. Transfection Assay for P450 Enzyme Induction
CV-1
HuH7 cell
PXR
RXR
PXR Expression
Plasmid
RXR
PXR
PXRE
Reporter Gene
Reporter Plasmid
Drug

44. Normalized Reporter Activity
Differential Activation of Human, Rabbit, and Rat PXR by CYP3A Inducers
PCN
rifampicin
lovastatin
clotrimazole 20 40 60 80
100
300
350
400
Normalized Reporter Activity

45. PXR Sequence Homology
Human PXR1
DNA
Ligand
Variation in ligand binding domain consistent with in vivo species differ-ences in response to inducers
Rabbit PXR1 94 82
Rat PXR1 96 76
Mouse PXR1 96 76
Xenopus ONR1 69 42
Human VDR 63 37

46. Amino Acid Differences in the Ligand Binding Domain of PXR
Val184
Val210
Glu263
Glu333
Thr414
rPXR
Asp178
Ser203
His260
Arg333
Phe184
Leu210
Asp263
Lys334
Ser414
mPXR
Gly178
Arg203
Tyr260
Arg333
Ser187
Leu213
Asp266
Glu337
Ile417
hPXR
Gly181
Leu206
Tyr263
His333
Zhang et al., Arch. Biochem. Biophys., 1999

47. Rat CYP4A1 Response Elements
-10kb
-2kb
+1 (gene)
Rat CYP4A1
-4850
-4466
DR1 (9/12)
384 bp
DR1 (9/12)
ATTTAAGGAAAgGGGTCAGACC------AACTAGGGTAaAGTTCAGTG
In 1995 Aldridge identified two response elements approximately 4 Kb upstream of the CYP4A1 gene.
The authors were able to show through gel shift and transfection studies (review this paper) that the more distal response element was non functional whereas the proximal element was functional and was necessary for induction of rat CYP4A1.
Element 1 not functional
Element 2 is a Functional PPRE
Proximal PPRE Identified by Aldridge et. al. Biochem. J. 306, , 1995

48. Analysis of the Human CYP4A11 Gene
Kawashima et. al., Archives of Biochemistry and Biophysics (2000) 378(2),
Sequenced bp upstream of gene, no PPRE identified. +1
Human CYP411
-2kb
-5kb
AAACAAGGGAATAGCCCAAAAG
-4493
DR1 (8/12)
-4472
-7kb
-10kb
AAAAGTGGGCAAAGGATATGCA
-7238
-7217
While the CYP4A11 gene sequence was reported in 2000, Kawashima was not able to identify a PPRE upstream of the CYP4A11 gene.
However, at the time of the report, data from the human genome project was not as accessible as it is today.
Analysis of the upstream region of human CYP4A11 on chromosome 1 reveals several potential PPREs with the two best (according to consensus) shown here. Interestingly, there is a potential response element in the same region as the two rat response elements, however a second element is not apparent in the human sequence.
Upstream analysis of the CYP4A11 gene located on chromosome 1 revealed two possible PPRE’s

49. Gel Shift Assay PPARa + - .5 1 2 + - .5 1 2 + - .5 1 2 RXRa - + .5 1 2
Rat
Human -4.5 kb
Human -7.5 kb
PPARa
RXRa
PPRE/PPARa/RXR
Data are mean plus or minus standard deviation of three replicates in the TaqMan assay.
Rat data are consistent with literature reports of EC50 for rat CYP4A induction by clofibric acid.
Human data are consistent with literature reports of EC50 for human CYP4A induction by clofibric acid.
Need to perform this experiment in dog hepatocytes when CYP4A primers and probes are validated.

50. Summary
Induction of metabolism is caused by many structurally unrelated xenobiotics.
Induction occurs mainly by transcriptional regulation of metabolizing enzymes and transporter proteins.
Nuclear receptors mediate the induction response by most xenobiotics.
Amino acid differences in the ligand-binding domain of the receptors are mainly responsible for the species differences in the induction of CYP450 enzymes.

51. Additional Reading
Parkinson, A.: Biotransformation of xenobiotics. In: Casarett and Doull’s Toxicology. The Basic Science of Poisons. Sixth edition (edited by C.D. Klaassen). McGraw Hill, New York, 2001.
Wang, H. and Negishi, M. (2003) Transcriptional regulation of cytochrome p450 2B genes by nuclear receptors. Curr Drug Metab. 4(6):
Bertilsson, G., Heidrich, J., Svensson, K., Asman, M., Jendeberg, L., Sydowbackman, M., Ohlsson, R., Postlind, H., Blomquist, P. and Berkenstam, A. (1998) Identification of a human nuclear receptor defines a new signaling pathway for CYP3A induction. Proc. Natl. Acad. USA. 95:
Blumberg, B., and Evans, R.M. (1998) Orphan nuclear receptors – new ligands and new possibilities. Genes Dev. 12:
Geick A., Eichelbaum M., and Burk O. (2001) Nuclear receptor response elements mediate induction of intestinal MDR1 by rifampin. J Biol Chem. 276(18):

52. Additional Reading
Goodwin B., Hodgson E., and Liddle C. (1999) The orphan human pregnane X receptor mediates the transcriptional activation of CYP3A4 by rifampicin through a distal enhancer module. Mol Pharmacol 56:
Honkakoski P. and Negishi M. (1998) Regulatory DNA elements of phenobarbital-responsive cytochrome P450 CYP2B genes. J Biochem Mol Toxicol 12:3-9.
Jones, S. A., Moore, L. B., Shenk, J. L., Wisely, G.B., Hamilton, G. A., McKee, D. D., Tomkinson, N. C. O., LeCluyse, E. L., Wilson, T. M., Kliewer, S. A. and Moore, J. T The pregnane X receptor, a promiscuous xenobiotic receptor that has diverged during evolution. Mol. Endocrinol. 14:
Wang, H., and LeCluyse E. L Role of orphan nuclear receptors in the regulation of drug metabolising enzymes. Clin. Pharmacokinet. 42: